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Orthogonal tip-to-tip nanocapillary alignment allows for easy detection of fluorescent emitters in femtomolar concentrations Po-Ling Chang, Michael Graf, Chao-Hsuan Hung, and Aleksandra Radenovic Nano Lett., Just Accepted Manuscript • DOI: 10.1021/acs.nanolett.8b00831 • Publication Date (Web): 04 Apr 2018 Downloaded from http://pubs.acs.org on April 4, 2018
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Orthogonal tip-to-tip nanocapillary alignment allows for easy detection of fluorescent emitters in femtomolar concentrations
Po-Ling Chang,*†§ Michael Graf,‡§ Chao-Hsuan Hung,† and Aleksandra Radenovic‡
† ‡
Department of Chemistry, Tunghai University, Taichung 40704, Taiwan
Laboratory of Nanoscale Biology, Institute of Bioengineering, School of Engineering, EPFL, 1015 Lausanne, Switzerland
Corresponding Author E-mail:
[email protected] Tel: +886-4-23590121#32246
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Abstract Here we present the realization of a novel fluorescence detection method based on the electromigration of fluorescent molecules within a nanocapillary combined with the laser excitation through a platinum (Pt)-coated nanocapillary. By using the Pt-nanocapillary assisted focusing of a laser beam we completely remove the background scattering on the tip of the electrophoretic nanocapillary. In this excitation geometry we demonstrate a thousandfold sensitivity enhancement (1.0 nM to 1.0 pM) compared to the detection in microcapillaries with epifluorescence illumination and fluorescence spectrophotometry. Due to significant electroosmotic flow, we observe decelerating migration of DNA molecules close to the tip of the electrophoretic nanocapillary. The reduced DNA translocation velocity causes a two-step stacking process of molecules in the tip of the nanocapillary and can be used as a way to locally concentrate molecules. The sensitivity of our method is further improved by continuous electrokinetic injection of DNA molecules followed by sample zone stacking on the tip of the nanocapillary. Concentrations ranging from 0.1 pM to 1.0 fM can directly be observed on the orifice of the electrophoretic nanocapillary. This is a thousand fold improvement compared to traditional capillary electrophoresis with laser-induced fluorescence. Keywords: nanocapillary, fluorescence, electroosmotic flow, glass nanopore, DNA translocation 2
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Due to the remarkable progress in the development of stable laser sources and ultra-sensitive detectors, fluorescence detection has become one of the most sensitive methods for the analysis of trace amounts of molecules. Besides instrumentation, improvements in the performance of the labeling agents, in terms of their quantum yield, photostability, spectral properties and biocompatibility, have helped to achieve high sensitivity and specificity. Therefore, fluorescence assays based on either high-performance liquid chromatography (HPLC) or capillary electrophoresis are now widely used in the analysis of the biomolecules, drugs, metabolites, nanomaterials and chemicals from environment and food. In conventional capillary electrophoresis, the sensitivity enhancements require a large quantity of analyte to be introduced into the capillary column to allow for sample stacking during electrophoretic migration and pre-concentration of the sample in the detection volume.1-2 Despite the fact that the analyte concentration can be increased in the detection volume, the sensitivity of fluorescence detection is still limited by strong Rayleigh and Raman scattering when a laser beam is focused on a solid container.3 Implementation of advanced illumination strategies with on-column detection of chromatographic or electrophoretic-based techniques is still challenging.4 To minimize light scattering and reduce background noise in the column, several strategies have been proposed: A sheath flow configuration can obtain a detection limit of 5 pM for dye-derivative of alanine.5 3
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Single-molecule
fluorescence
detection
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in
microcapillaries
and
microfluidic devices6 based on time-correlated single-photon counting7, resulted in a detection limit of 0.1-10 pM. Determination of microRNA to a quantitative limit of 500 fM by a single-molecule two-color coincident detection method combined with a single photon avalanche photodiode detector has been demonstrated.8 Moreover, a wide dynamic range (1.0 pM- 1.0 mM) for 5-carboxyl-tetramethylrhodamine detection was achieved by using a cascade of four fiber-optic beam splitters with photon counters.9 In addition to the improvement by optical design, on-column concentration based on electric field amplification followed by polymer stacking can also provide a sensitivity enhancement reaching up to 0.1 pM-1.0 nM.10-11 The methods mentioned above are remarkable for specific applications. However, their sensitivity is insufficient to detect small amounts of molecules, especially if the analyte concentration is below the femtomolar range.12 In conventional two-dimensional fluorescence assays, single molecule detection based on wide-field illumination in combination with an electron multiplying charged-coupled device (EMCCD) detector can achieve the highest sensitivities. In practice, the background can be further minimized by using an evanescence wave illumination13-14 or highly inclined and laminated optical sheet (HILO) microscopy.12, 15
However, a subnanomolar detection limit can only be reached if there is no sample 4
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preconcentration as reported in previous studies.16 In another recent report, subfemtomolar detection of trace amount biomolecules was visualized by HILO microscopy.12 Nevertheless, the improved sensitivity has been reached only in cellular imaging methods, mainly due to confinement provided by the cell itself. Within a single cell, the diffusion volume of the fluorescent molecules is reduced to a few picoliters. For instance, attomole analytes contained in a prototypical cell volume (HeLa 30 µm diameter, 2-3 µm height) have a local concentration in the nanomolar range. This falls well into the detectable concentration range for an EMCCD. In other words, it is difficult to observe fluorescence intensity using an EMCCD if the molecular concentration is below subnanomolar and the molecules are able to freely diffuse in the full sample volume. Therefore, slowdown and confinement of the molecular motion in the focal plane of the excitation laser appears to be the only solution to improve the sensitivity during fluorescence imaging. An interesting approach for single molecule detection is the counting of single molecules from numerous femtoliter arrays to form a digital data format.17 Due to the ultralow concentration of the sample and the small excitation volume of the laser beam18 the stochastic fluctuation of loaded molecules19 and the Poisson distribution of sampling20 can cause false negative results and thus increase measurement uncertainty. Sample enrichment looks like to be the best strategy to increase the sensitivity of single 5
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molecule arrays to femtomolar level and to overcome the negative effect of Poisson sampling.21 Similarly, increasing the sample injection time prior to electrophoresis may not only increase the sensitivity, but also provide a good solution to decrease the uncertainty that is caused by the fluctuation of the injected molecules in a ultra-diluted sample.19 Conversely, label-free techniques such as nanopore sensing have shown high-speed single molecule detection by resistive pulse observation.22-24 Exploiting the same sensing principles, nanocapillaries25 were used to study DNA-protein complexes26-27, to detect single nucleotide polymorphisms28 and were used to deliver single nanoparticles.29 Even though the single molecule translocation techniques are now well established, the detectable concentrations still range from submillimolar to nanomolar level.25,
30-32
Moreover, the subnanomolar sensitivity can be further
improved by molecular slowdown at a nanobridge of a nanocapillary.33 Recently, Hoogerheide et al. have shown the migratory behavior of DNA near a solid-state nanopore by balancing the applied pressure and the voltage gradient.34 The slowdown effect can be used to trap the DNA near the nanopore and allows to thread the DNA multiple times into the pore. The trapping of λ-phage DNA at the tip of a microcapillary using a combination of electroosmotic flow (EOF), pressure-driven flow and electrophoretic miagration of DNA has been demonstrated by Rempfer et 6
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al.35 Furthermore, Freedman et al. reported an ultra-sensitive method for nanopore sensing of lamda DNA.36 A sensitivity of 5 fM lamda DNA could be detected by dielectrophoretic trapping followed by current drop detection caused by translocation through the nanopore. In this work, we go beyond the standard use of nanocapillaries in translocation experiments. In our experimental setup, two nanocapillaries are used: one to localize DNA molecules on its tip (electrophoretic nanocapillary), the other to minimize the size of the laser spot by focusing through a nanocapillary coated with a thin metal film (focusing nanocapillary). In this novel dual-nanocapillary-based instrument the fluorescence burst, produced by fast electrophoretically migrating DNA in femtomolar concentrations, can be routinely observed using an EMCCD camera. A two-step DNA stacking–mechanism in the electrophoretic nanocapillary is reported for the first time in our study. We demonstrated that using a simple nanocapillary is sufficient to increase the sensitivity of fluorescence detection without any sample preconcentration37 or signal amplification.31 As shown in Figure 1a, the electrophoretic nanocapillary is installed on an inverted microscope. The laser beam excitation is achieved through a Pt-coated nanocapillary. The tip of the two nanocapillaries are aligned to be as close as possible (Figure 1a, zoom) in order to excite fluorescent molecules directly when they migrate out of the electrophoretic nanocapillary. The sizes of the electrophoretic nanocapillary and 7
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Pt-coated nanocapillary have been verified by scanning electron microscopy (SEM) (Figure 1b, c.). In a preliminary experiment, similar fluorescence intensities and burst sizes were observed by using pore sizes of the electrophoretic nanocapillary ranging from 20-100 nm. This phenomena can be explained by the theoretical calculation of the electric field amplification near the tip of the nanocapillary:38 a smaller pore size would not concentrate the molecule into a narrow detection volume but rather speed up the molecule near the nanopore. Therefore, the typical size of the electrophoretic nanocapillary used was 20 nm. All nanocapillaries were fabricated using a previously published method.25 Atomic layer deposition (ALD) was used to deposit platinum on a nanocapillary to reach a target opening diameter of 50 nm. In traditional capillary electrophoresis with end-column laser-induced fluorescence a significant background signal is commonly observed from the capillary wall when a 5 mW laser beam is focused on the end of the capillary (Figure 2a-b). Due to the large background noise, the detection limit of conventional laser-induced fluorescence is 470 pM (signal to noise = 3) as shown in Figure 2b. In order to reduce the background noise originating from the scattering of the excitation laser beam on the capillary wall (Figure 2d), we have introduced a metal-coated nanocapillary that is used to focus the laser light (Figure 2c-f) onto the electrophoretic capillary in an orthogonal configuration. Strong scattering can also occur on the tip of the electrophoretic 8
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nanocapillary due to the coaxial focusing of the laser beam by the objective (Figure 2a,b). The scattering is significantly reduced by focusing the laser beam through a Pt-coated nanocapillary to form a small probing volume (~1 pL) (Figure 2c-f) that allows to confine the laser to the orifice of the electrophoretic nanocapillary and minimize the interference from scattering. During the alignment between the two nanocapillaries, a weak scattering can be observed when the laser beam strikes above the orifice of the electrophoretic nanocapillary (Figure 2c). However, the background can completely vanish by carefully aligning the electrophoretic nanocapillary to the focusing nanocapillary in order to reach the so-called tip-to-tip configuration (Figure 2e). The zero background effect is similar to total internal reflection microscopy, which allows to detect weak fluorescence signals without interference of scattering. In this way, we achieve a significant reduction in both the background and the noise (647 ± 38 a.u.) (Figure 2e) as compared to epifluorescence configuration in Figure 2a (879 ± 91 a.u.). Figure 2 c-f show the laser excitation of a Pt-coated nanocapillary where the Rayleigh and Raman scattering have been reduced close to the level of dark current of the EMCCD (645 ± 40 a.u.). Although the laser excitation power (now set to 50 µW) has been reduced to only 1% of the initial laser power, we reached a detection limit of 455 pM using microcapillaries (Figure 2f), which is slightly better than in Figure 2b. 9
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In nanocapillaries, the negligible background increases the sensitivity of the fluorescence detection from 1.0 nM to 1.0 pM with a detection limit at 0.63 pM (Figure 3a-3d). The direct detection of the fluorescent bursts from the fast-moving, single emitter-labeled DNA molecule is about three orders of magnitude better than the one achieved by conventional fluorescence methods using an EMCCD (Figure 2a, b, f) or a photomultiplier tube as the transducer in fluorospectrophotometer (Figure S1). Figure 3h shows a linear range from 1.0 nM to 1.0 pM (Figure 3a-3d, R2 = 0.96). This concentration range is measured by filling the DNA sample into the capillary by pressure followed by electromigration through the electrophoretic nanocapillary. To further increase the sensitivity of our method we loaded low-abundant samples by prolonged electrokinetic injection in order to drive more molecules into the capillary column. Once in the column, the DNA molecules are driven from the inlet of microcapillary to the orifice by electrophoresis. In addition to increasing the load of DNA molecules the prolonged electrokinetic injection may also be beneficial in reducing the stochastic fluctuations in ultra-low concentration samples.19 We observe fluorescent bursts from concentrations ranging from 1.0-100 fM DNA using an EMCCD camera (Figure 3e-g). As mentioned above, the electric field amplification near the orifice of the nanocapillary can speed up molecule migration,38 and consequently, retain a similar linear velocity comparable with microcapillary 10
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electrophoresis. In fact, the eletrophoretic mobility of DNA passing through the nanocapillary is 2.80 × 10ିସ cmଶ sିଵ V ିଵ (Figure 4, Movie S1) which is slightly less than traditional capillary electrophoresis (3.07 × 10ିସ cmଶ sିଵ V ିଵ, Figure S2b), indicating that there is no significant difference in the DNA mobility between microcapillaries and nanocapillaries. Therefore, a short nanocapillary can easily be elongated to the required length without compromising measurement time. Figure S2a shows that hydrodynamically injected molecules yield 833-fold less fluorescence than electrokinetic injection during 10 seconds (Figure S2b). This means that electrokinetic injection allows to load a greater number of molecules into the capillary than pressure loading. This significant difference is due to the electric field amplification within the sample solution in low ionic strength condition.39 In addition, capillary zone electrophoresis of the DNA molecules can be considered as an on-column concentration where the injected flat sample zone may form a narrow Gaussian band during molecular migration through the capillary (Figure S2b). Nevertheless, with sample loading times of up to 3 minutes (Figure S2c), a broader band in the electropherogram is observed, indicating that the fluorescence area is roughly proportional to the injection time (18.6-fold). The sharp Gaussian peak is lost as a result of sample overloading in a simple buffer system. The fluorescence area in Figure S2c is 1.5 × 104-fold higher than the one obtained for static excitation 11
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(pressure driven DNA). The band broadening leads to a decrease of the fluorescence intensity but at the same time extends the observation time of DNA molecules so that one can monitor them as they reach the nanopore (Figure 4a-f, Movie S1). The fluorescence burst intensity still shows a linearity (R2 = 0.88, Figure 3h) regardless of the band broadening caused by sample overloading (Figure S2c). Contrary to traditional capillary electrophoresis, which uses a high viscosity linear polymer solution to stack the sample,10 we used only simple buffer solutions. Thus, the greatly improved sensitivity from Figure 3e-g can only be attributed to the prolonged sample injection and not to the efficiency of the electrophoretic stacking. As shown in Figure 3a-d, both the DNA and the buffer concentrations should be identical through the whole capillary, therefore we do not expect the formation of a Gaussian peak during electrophoretic migration. This points towards an unknown stacking process causing DNA slowdown during electromigration inside the nanocapillary. To investigate our hypothesis and to observe the dynamics of electrophoretically migrating fluorescent molecules, we took a movie at the tip of the nanocapillary (Figure 4). During the electrophoretic migration, the fluorescent molecules accumulate on the orifice of the nanocapillary as shown in Figure 4a. In the following moments, before the first molecules are ejected, more DNA molecules accumulate in the nanocapillary tip and form a separate accumulation zone (Figure 12
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4b). The two DNA zones co-exist at the tip of the nanocapillary for a short period of time (Figure 4c), until the first stack of accumulated, negatively charged DNA molecules are ejected quickly from the nanopore (Figure 4d) due to the strong electric field at the tip.38 Similarly, the second DNA accumulation zone will follow the first one and migrate out of the nanocapillary (Figure 4e). At the end, all DNA molecules will pass through the nanopore and provide an enhanced fluorescence intensity in the form of bursts due to the accumulation zones (Figure 4f). Besides the extracted frames from Movie S2 we show the dynamics of DNA migration in the nanocapillary as a temporal evolution of the fluorescence signals either as a simple kymograph (Figure 4g,i) or as a line plot (Figure 4h). The two-stage sample concentrating behavior during nanocapillary electrophoresis demonstrates the important role of the nanopore in the sensitivity improvement of laser-induced fluorescence detection. The first sample accumulation zone at the tip of the nanocapillary (Figure 4a) may be caused by several factors: first, the DNA might be slowed down at the orifice when a lot of DNA molecules arrive at the same time at the nanopore in the presence of an overlapping eletrical double layer.40 Second, DNA molecules may also be adsorbed to the surface of bare fused silica14, especially when they are near the tip of nanocapillary and confined to a limited volume. Third, the EOF could also play a critical role by effectively slowing down the DNA translocation. Not only can the 13
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DNA molecules be stacked at the tip of the nanocapillary (Figure 4), but they can also be pushed back to the cis end in the case where the EOF is larger than the DNA mobility (Figure 5). The thinning of electrical double layer of the capillary wall can be achieved by the addition of ethanol into the trans chamber,41 thus counteracting the EOF and causing migration of DNA towards the cis end again (Figure 5b). Movie S3 demonstrates how the EOF can cause the DNA to accumulate inside the capillary when DNA migrates against the EOF (Figure 5). To further investigate the role of EOF we have designed a control experiments: We have created two EOF conditions in microcapillaries that have been entirely (Figure S3a) or partially (Figure S3b-f) coated by polyvinylpyrrolidone (PVP) to suppress EOF.42 Since tracking of single DNA molecules at this timescales is challenging using a low NA objecive, we have measured the dynamics of fluorescently labeled beads (20 nm) inside the coated capillary (Figure S3). The beads inside the completely coated capillary displayed an uniform velocity during electromigration (Figure S3a, Movie S4). The EOF should have been largely suppressed in Figure S3a and we made sure that beads can migrate to the trans end as fast as possible. In contrast, in a bare microcapillary created in the way that the region close to the tip has no PVP (Figure S3b-f), the fluorescent beads displayed significantly lower velocities near the outlet (Movie S5) while still migrating from the cis to the trans side. Moreover, the arrow in Figure S3b-f shows 14
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beads that displayed a U-turn behavior, i.e. beads that migrated back to the cis side when they arrived at the PVP-free region of the capillary where the EOF should be larger. Consequently, EOF-induced slowdown of beads caused collisions with beads moving in the opposite direction, which in turn lead to bead aggregation and brighter fluorescence (Movie S5). At the end, all the beads will still migrate to the trans chamber since the partially generated EOF is not sufficient to reverse the migration direction. This result demonstrates that even partially generated EOF is enough to reduce the velocity of charged molecules and to concentrate them at the tip of the nanocapillary (Figure 4). Once the first molecular accumulation occurred, migration of DNA molecules may suffer another counterforce that originates from the electric repulsion of the negative charges that are already accumulated in the tip. These repulsed DNA molecules can form a second stacking zone (Figure 4b-c). Consequently, ultra-low concentration of DNA molecules can be observed at the nanopore by combining sample concentration in the nanocapillary with laser excitation using the focusing nanocapillary. In this work, we have introduced and characterized a novel dual-nanocapillary device that allows to concentrate charged molecules at the tip of the nanocapillary during
electrophoretic
migration.
For
low
abundance
samples
continuous
electrokinetic injection increases the detectability and decreases the error from 15
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Poisson sampling. On the other hand, all molecules injected into the capillary will be confined into a limited space and can be detected by a laser-spot excitation during passage through the nanopore. Consequently, the statistical errors limiting the development of ultra-sensitive detection methods can be decreased. Furthermore, we have observed for the first time the reduction of the DNA mobility due to the EOF. The slowdown of DNA molecules led to DNA stacking at the orifice of the nanocapillary followed by the creation of a second sample stacking zone. The creation of the two stacking zones is due to the accumulation of negative charges of DNA that repel each other. Ultimately, a millionfold improvement of sensitivity can be achieved with our method. We demonstrated femtomolar sensitivity that is comparable to real-time PCR12 and may benefit in detection of the ultra-low abundance biomarkers from body fluid43 without any sample preconcentration44 or signal/molecule amplification like PCR or rolling circle amplification45. Furthermore, we expect that attomolar molecule detection might be realized in the case that one uses preconcentration methods like sweeping,46 electric field amplification39, 47 or sample stacking by nanogel.48 Thus, our method is not only beneficial to the ultrasensitive analysis of essential molecules but also potentially helpful for the determination of trace circulating biomarkers in various body fluids.
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In addition to sensitivity improvements for fluorescence detection, DNA translocations may also benefit from the femtomolar sensitivity of nanocapillary electrophoresis. For instance, real-time translocation measurements of ultra-low abundance biomolecules such as messenger ribonucleoprotein (mRNP)49 or RNAP– DNA transcription complex50 extracted from individual living cells become possible not only because of the remarkable sensitivity but also due to the flexibility that the capillary offer to directly withdraw these molecules through a cytoplasmic and/or nuclear membrane for single cell nanobiopsy.51 Furthermore, the discriminating power for DNA folding analysis52 by glass nanocapillary may be limited by short dwell times during DNA translocation. Therefore, the possibility to control EOF to adjust the DNA translocation speed via visual feedback might be useful in optimizing the translocation speed required for nanopore based single molecule sensing.
ASSOCIATED CONTENT Supporting Information Experimental details on nanocapillary fabrication and instrumentation, DNA electropherograms via hydrodynamic or electrokinetic injection, movies of the observation of fluorescence burst from orifice of a nanocapillary, DNA behaviors inside nanocapillary, and EOF effects on bead migration near the end of microcapillary. AUTHOR INFORMATION Corresponding Author *E-mail:
[email protected] ORCID Po-Ling Chang: 0000-0002-0398-3220 17
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Michael Graf: 0000-0001-6201-7471 Aleksandra Radenovic: 0000-0001-8194-2785 Contributions P.-L.C. and M.G. prepared all nanocapillaries and data analysis. P.-L.C. performed dual-nanocapillary instrumentation. C.-H.H. performed nanocapillary movie collection, A.R. designed atomic layer deposition of nanocapillary and supervised this work. P.-L.C., A.R., and M.G. wrote the manuscript. All authors discussed the results and commented on the manuscript. §
P.-L.C. and M.G. contributed equally to this work.
Funding The authors would like to thank the Swiss National Science Foundation (Grant numbers 200021_153653, BSCGI0_157802) and Ministry of Science and Technology, Taiwan for the partial MOST106-2113-M-029-003).
funding
support
(MOST104-2918-I-029-003,
ACKNOWLEDGMENTS We are grateful to the Center of Micronanotechnology, EPFL and Ms. Y.-T. Lee of Instrumentation Center, National Taiwan University for the help in the SEM and atomic layer deposition experiments. Notes The authors declare no competing financial interests. References (1) Kawai, T.; Ueda, M.; Fukushima, Y.; Sueyoshi, K.; Kitagawa, F.; Otsuka, K. Toward 10 000-fold sensitivity improvement of oligosaccharides in capillary electrophoresis using large-volume sample stacking with an electroosmotic flow pump combined with field-amplified sample injection. Electrophoresis 2013, 34, 2303-2310. (2) Breadmore, M. C.; Quirino, J. P. 100,000-fold concentration of anions in capillary zone electrophoresis using electroosmotic flow controlled counterflow isotachophoretic stacking under field amplified conditions. Anal. Chem. 2008, 80, 6373-6381. (3) Goodwin, P. M.; Ambrose, W. P.; Keller, R. A. Single-Molecule Detection in Liquids by Laser-Induced Fluorescence. Acc. Chem. Res. 1996, 29, 607-613. (4) Scanlan, C.; Lapainis, T.; Sweedler, J. V. Light-Based Detection Methods for Capillary Electrophoresis. In Handbook of capillary and microchip electrophoresis and associated microtechniques, 3rd ed.; Landers, J. P. CRC press, 2007, 305. 18
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(5) Cheng, Y.; Dovichi, N. Subattomole amino acid analysis by capillary zone electrophoresis and laser-induced fluorescence. Science 1988, 242, 562-564. (6) Haab, B. B.; Mathies, R. A. Single-molecule detection of DNA separations in microfabricated capillary electrophoresis chips employing focused molecular streams. Anal. Chem. 1999, 71, 5137-5145. (7) Zander, C.; Drexhage, K. H.; Han, K. T.; Wolfrum, J.; Sauer, M. Single-molecule counting and identification in a microcapillary. Chem. Phys. Lett. 1998, 286, 457-465. (8) Neely, L. A.; Patel, S.; Garver, J.; Gallo, M.; Hackett, M.; McLaughlin, S.; Nadel, M.; Harris, J.; Gullans, S.; Rooke, J. A single-molecule method for the quantitation of microRNA gene expression. Nat. Methods 2006, 3, 41-46. (9) Dada, O. O.; Essaka, D. C.; Hindsgaul, O.; Palcic, M. M.; Prendergast, J.; Schnaar, R. L.; Dovichi, N. J. Nine Orders of Magnitude Dynamic Range: Picomolar to Millimolar Concentration Measurement in Capillary Electrophoresis with Laser Induced Fluorescence Detection Employing Cascaded Avalanche Photodiode Photon Counters. Anal. Chem. 2011, 83, 2748-2753. (10) Yang, T.-H.; Ou, D.-L.; Hsu, C.; Huang, S.-H.; Chang, P.-L. Comparative microRNA detection from precursor-microRNA-transfected hepatocellular carcinoma cells by capillary electrophoresis with dual-color laser-induced fluorescence. Electrophoresis 2012, 33, 2769-2776. (11) Jiang, R.-M.; Chang, Y.-S.; Chen, S.-J.; Chen, J.-H.; Chen, H.-C.; Chang, P.-L. Multiplexed microRNA detection by capillary electrophoresis with laser-induced fluorescence. J. Chromatogr. A 2011, 1218, 2604-2610. (12) Lin, Y.-Z.; Ou, D.-L.; Chang, H.-Y.; Lin, W.-Y.; Hsu, C.; Chang, P.-L. Simultaneous visualization of the subfemtomolar expression of microRNA and microRNA target gene using HILO microscopy. Chem. Sci. 2017, 8, 6670-6678. (13) Heilemann, M.; van de Linde, S.; Schüttpelz, M.; Kasper, R.; Seefeldt, B.; Mukherjee, A.; Tinnefeld, P.; Sauer, M. Subdiffraction-Resolution Fluorescence Imaging with Conventional Fluorescent Probes. Angew. Chem. Int. Ed. 2008, 47, 6172-6176. (14) Kang, S. H.; Shortreed, M. R.; Yeung, E. S. Real-Time Dynamics of Single-DNA Molecules Undergoing Adsorption and Desorption at Liquid−Solid Interfaces. Anal. Chem. 2001, 73, 1091-1099. (15) Tokunaga, M.; Imamoto, N.; Sakata-Sogawa, K. Highly inclined thin illumination enables clear single-molecule imaging in cells. Nat. Methods 2008, 5, 159-161. (16) Ho, S.-L.; Chan, H.-M.; Ha, A. W.-Y.; Wong, R. N.-S.; Li, H.-W. Direct Quantification of Circulating MiRNAs in Different Stages of Nasopharyngeal Cancerous Serum Samples in Single Molecule Level with Total Internal Reflection 19
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Fluorescence Microscopy. Anal. Chem. 2014, 86, 9880-9886. (17) Gorris, H. H.; Walt, D. R. Analytical chemistry on the femtoliter scale. Angew. Chem. Int. Ed. Engl. 2010, 49, 3880-3895. (18) Haab, B. B.; Mathies, R. A. Single molecule fluorescence burst detection of DNA fragments separated by capillary electrophoresis. Anal. Chem. 1995, 67, 3253-3260. (19) Chen, D.; Dovichi, N. J. Single-Molecule Detection in Capillary Electrophoresis: Molecular Shot Noise as a Fundamental Limit to Chemical Analysis. Anal. Chem. 1996, 68, 690-696. (20) Walt, D. R. Optical methods for single molecule detection and analysis. Anal. Chem. 2013, 85, 1258-1263. (21) Cohen, L.; Hartman, M. R.; Amardey-Wellington, A.; Walt, D. R. Digital direct detection of microRNAs using single molecule arrays. Nucleic Acids Res. 2017. (22) Feng, J.; Liu, K.; Bulushev, R. D.; Khlybov, S.; Dumcenco, D.; Kis, A.; Radenovic, A. Identification of single nucleotides in MoS2 nanopores. Nat. Nanotechnol. 2015, 10, 1070-1076. (23) Keyser, U. F. Enhancing nanopore sensing with DNA nanotechnology. Nat. Nanotechnol. 2016, 11, 106-108. (24) Traversi, F.; Raillon, C.; Benameur, S. M.; Liu, K.; Khlybov, S.; Tosun, M.; Krasnozhon, D.; Kis, A.; Radenovic, A. Detecting the translocation of DNA through a nanopore using graphene nanoribbons. Nat. Nanotechnol. 2013, 8, 939-945. (25) Steinbock, L. J.; Steinbock, J. F.; Radenovic, A. Controllable shrinking and shaping of glass nanocapillaries under electron irradiation. Nano Lett. 2013, 13, 1717-1723. (26) Bulushev, R. D.; Marion, S.; Radenovic, A. Relevance of the Drag Force during Controlled Translocation of a DNA–Protein Complex through a Glass Nanocapillary. Nano Lett. 2015, 15, 7118-7125. (27) Bulushev, R. D.; Marion, S.; Petrova, E.; Davis, S. J.; Maerkl, S. J.; Radenovic, A. Single Molecule Localization and Discrimination of DNA-Protein Complexes by Controlled Translocation Through Nanocapillaries. Nano Lett. 2016, 16, 7882-7890. (28) Kong, J.; Zhu, J.; Keyser, U. F. Single molecule based SNP detection using designed DNA carriers and solid-state nanopores. Chem. Commun. 2016, 53, 436-439. (29) Yu, Y.; Sundaresan, V.; Bandyopadhyay, S.; Zhang, Y.; Edwards, M. A.; McKelvey, K.; White, H. S.; Willets, K. A. Three-Dimensional Super-resolution Imaging of Single Nanoparticles Delivered by Pipettes. ACS Nano 2017, 11, 10529-10538. (30) Kong, J.; Bell, N. A.; Keyser, U. F. Quantifying Nanomolar Protein 20
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Concentrations Using Designed DNA Carriers and Solid-State Nanopores. Nano Lett. 2016, 16, 3557-3562. (31) Lin, X.; Ivanov, A. P.; Edel, J. B. Selective single molecule nanopore sensing of proteins using DNA aptamer-functionalised gold nanoparticles. Chem. Sci. 2017, 8, 3905-3912. (32) Nascimento, R. A.; Özel, R. E.; Mak, W. H.; Mulato, M.; Singaram, B.; Pourmand, N. Single cell “glucose nanosensor” verifies elevated glucose levels in individual cancer cells. Nano Lett. 2016, 16, 1194-1200. (33) Cadinu, P.; Paulose Nadappuram, B.; Lee, D. J.; Sze, J. Y. Y.; Campolo, G.; Zhang, Y.; Shevchuk, A.; Ladame, S.; Albrecht, T.; Korchev, Y.; Ivanov, A. P.; Edel, J. B. Single Molecule Trapping and Sensing Using Dual Nanopores Separated by a Zeptoliter Nanobridge. Nano Lett. 2017, 17, 6376-6384. (34) Hoogerheide, D. P.; Lu, B.; Golovchenko, J. A. Pressure–Voltage Trap for DNA near a Solid-State Nanopore. ACS Nano 2014, 8, 7384-7391. (35) Rempfer, G.; Ehrhardt, S.; Laohakunakorn, N.; Davies, G. B.; Keyser, U. F.; Holm, C.; de Graaf, J. Selective Trapping of DNA Using Glass Microcapillaries. Langmuir 2016, 32, 8525-8532. (36) Freedman, K. J.; Otto, L. M.; Ivanov, A. P.; Barik, A.; Oh, S.-H.; Edel, J. B. Nanopore sensing at ultra-low concentrations using single-molecule dielectrophoretic trapping. Nat. Commun. 2016, 7, 10217. (37) Kim, B. Y.; Swearingen, C. B.; Ho, J.-a. A.; Romanova, E. V.; Bohn, P. W.; Sweedler, J. V. Direct Immobilization of Fab‘ in Nanocapillaries for Manipulating Mass-Limited Samples. J. Am. Chem. Soc. 2007, 129, 7620-7626. (38) Bulushev, R. D.; Steinbock, L. J.; Khlybov, S.; Steinbock, J. F.; Keyser, U. F.; Radenovic, A. Measurement of the Position-Dependent Electrophoretic Force on DNA in a Glass Nanocapillary. Nano Lett. 2014, 14, 6606-6613. (39) Jung, B.; Bharadwaj, R.; Santiago, J. G. Thousandfold signal increase using field‐amplified sample stacking for on‐chip electrophoresis. Electrophoresis 2003, 24, 3476-3483. (40) Haywood, D. G.; Saha-Shah, A.; Baker, L. A.; Jacobson, S. C. Fundamental Studies of Nanofluidics: Nanopores, Nanochannels, and Nanopipets. Anal. Chem. 2015, 87, 172-187. (41) Valkó, I. E.; Sirén, H.; Riekkola, M. L. Characteristics of electroosmotic flow in capillary electrophoresis in water and in organic solvents without added ionic species. J. Microcolumn Sep. 1999, 11, 199-208. (42) Chen, Y.-C.; Chang, P.-L. Baseline separation of amino acid biomarkers of hepatocellular carcinoma by polyvinylpyrrolidone-filled capillary electrophoresis with light-emitting diode-induced fluorescence in the presence of mixed micelles. Analyst 21
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2015, 140, 847-853. (43) Mitchell, P. S.; Parkin, R. K.; Kroh, E. M.; Fritz, B. R.; Wyman, S. K.; Pogosova-Agadjanyan, E. L.; Peterson, A.; Noteboom, J.; O'Briant, K. C.; Allen, A.; Lin, D. W.; Urban, N.; Drescher, C. W.; Knudsen, B. S.; Stirewalt, D. L.; Gentleman, R.; Vessella, R. L.; Nelson, P. S.; Martin, D. B.; Tewari, M. Circulating microRNAs as stable blood-based markers for cancer detection. Proc. Natl. Acad. Sci. U. S. A. 2008, 105, 10513-10518. (44) Pang, Y.; Wang, C.; Wang, J.; Sun, Z.; Xiao, R.; Wang, S. Fe3O4@Ag magnetic nanoparticles for microRNA capture and duplex-specific nuclease signal amplification based SERS detection in cancer cells. Biosens. Bioelectron. 2016, 79, 574-580. (45) Zhang, Z.; Wang, Y.; Zhang, N.; Zhang, S. Self-assembly of nucleic acid molecular aggregates catalyzed by a triple-helix probe for miRNA detection and single cell imaging. Chem. Sci. 2016, 7, 4184-4189. (46) Sanuki, R.; Sueyoshi, K.; Endo, T.; Hisamoto, H. Double Sweeping: Highly Effective Sample Preconcentration Using Cationic and Anionic Micelles and Its Application to a Multiple Enzyme Activity Assay. Anal. Chem. 2017, 89, 6505-6512. (47) Sustarich, J. M.; Storey, B. D.; Pennathur, S. Field-amplified sample stacking and focusing in nanofluidic channels. Phys. Fluids 2010, 22, 112003. (48) Durney, B. C.; Bachert, B. A.; Sloane, H. S.; Lukomski, S.; Landers, J. P.; Holland, L. A. Reversible phospholipid nanogels for deoxyribonucleic acid fragment size determinations up to 1500 base pairs and integrated sample stacking. Anal. Chim. Acta 2015, 880, 136-144. (49) Grünwald, D.; Singer, R. H.; Rout, M. Nuclear export dynamics of RNA– protein complexes. Nature 2011, 475, 333. (50) Raillon, C.; Cousin, P.; Traversi, F.; Garcia-Cordero, E.; Hernandez, N.; Radenovic, A. Nanopore detection of single molecule RNAP-DNA transcription complex. Nano Lett. 2012, 12, 1157-1164. (51) Actis, P.; Maalouf, M. M.; Kim, H. J.; Lohith, A.; Vilozny, B.; Seger, R. A.; Pourmand, N. Compartmental genomics in living cells revealed by single-cell nanobiopsy. ACS Nano 2013, 8, 546-553. (52) Steinbock, L. J.; Otto, O.; Chimerel, C.; Gornall, J.; Keyser, U. F. Detecting DNA folding with nanocapillaries. Nano Lett. 2010, 10, 2493-2497.
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Figures (single column) and Figure captions
Figure 1. Schematic diagram of the experimental setup. a) One nanocapillary is used for electrophoresis while a platinum coated (Pt)-nanocapillary delivers the optical excitation. The electrophoretic nanocapillary was connected through a flexible microcapillary to facilitate sample injection, and buffer exchange. The electrophoretic nanocapillary is aligned to the Pt-deposited nanocapillary in a tip-to-tip manner to diminish scattering resulting from the small laser spot in the orifice of the Pt-nanocapillary. The SEM micrographs display typical pore sizes of b) the electrophoretic nanocapillary just after pulling (left panel) and final size of the pore (right panel) of 20 nm after electron irradiation induced shrinking c) focusing nanocapillary just after pulling (left panel) and 50 nm after atomic layer deposition of Pt (right panel).
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Figure 2. Comparison of coaxial illumination and nanocapillary focusing effect on the scattering from both traditional microcapillary (right column) and nanocapillary (middle column). Working in epifluorescence excitation as illustrated in the top left panel produces fluorescence signals in both capillaries: nanocapillary a) and microcapillary b), however, they exhibit strong scattering and consequently high background noise. By using the nanocapillary assisted focusing (middle row schematics), weak scattering can be observed if the laser beam hits c) outer wall of the nanocapillary or d) inner wall of the microcapillary. The scattering of the nanocapillary can be avoided entirely e) by aligning a laser just below the orifice of the nanocapillary (by raising the z-axis of the electrophoretic nanocapillary less than 1.0 µm) as shown in the schematics in the bottom left panel. However, in the case of a microcapillary the scattering may still disturb the fluorescence detection even with a properly aligned focusing nanocapillary as shown in f). The single-dye-labeled DNA (1.0 nM) was injected into the micro/nanocapillary (a. b. f) by syringe pump in order to compare the effect of scattering on the observed fluorescence.
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Figure 3. The performance of the dual-nanocapillary instrumentation for fluorescent DNA detection. The DNA was diluted by 100 mM Tris-borate buffer (pH 8.0) and prefilled into the whole capillary by a syringe pump (pressure driven prefilling) followed by turning a power supply on to migrate the DNA in the observation volume. Panels a)-d) show corresponding fluorescence micrographs for the following concentrations of Alexa Fluor 647 labeled oligonucleotide a) 1.0 nM, b) 0.1 nM, c) 10 pM, d) 1.0 pM, respectively. For lower DNA concentrations nanocapillary prefilling was achieved by electrokinetic injection (10 kV for 3 minutes) followed by electromigration via 10 kV driving force until the orifice of the nanocapillary was reached. The DNA molecules were diluted in water to reach final concentrations of e) 100 fM, f) 10 fM and g) 1.0 fM, respectively. The linear plot in h) is obtained from the mean fluorescence intensity in the region of interest for each concentration. The pore size of the electrophoretic nanocapillary was set to 20-30 nm, while the focusing nanocapillary was about 50 nm after atomic layer deposition. All the figures are treated in the same. Single frame images are displayed and the brightness and contrast were adjusted for better visibility of the small fluorescence bursts.
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Figure 4. Dynamics of the fluorescence intensity under constant DNA electrophoresis conditions. Movie S2 was used to extract the frames a-f). At the start of the experiment DNA molecules accumulate at the tip as shown in a) and cause a fast buildup of DNA molecules in the second zone near the tip b). The condition in which the two zones in the nanocapillary reach the highest DNA concentrations, is best depicted in c). Shortly after, DNA molecules get accumulated at the nanocapillary tip and are ejected from the nanocapillary, d) resulting in the loss of the fluorescence from that region. Concomitantly, in the second zone the DNA molecules slow down and accumulate observable by a dramatic increase in the fluorescence d). As most of the molecules are ejected, both zones display decrease in the fluorescence e)-f). The dynamics of the DNA migration in the nanocapillary can be monitored as a temporal evolution of mean fluorescence signals either as a simple kymograph as show in i) or as a line plot shown in h). Red and blue lines in h) correspond to the mean fluorescence signals measured at the tip zone (red ROI) and in the second zone (blue ROI). The two zones are indicated in g). All fluorescence images (Movie S2) are collected at 647 nm laser excitation (5 mW) using a 10X objective and a 30-ms exposure time. The electric field used in the DNA imaging was 240 V/cm in the presence of 400 mM Tris-borate buffer (pH 8.0).
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Figure 5. The electroosmotic flow affects DNA migration and the fluorescence signal during electrophoresis. In a) when DNA mobility is larger than the EOF mobility, DNA migrates to the trans side of the chamber. Under constant electrophoresis condition buffer gets depleted and trans side becomes more basic, which in turn increases the EOF mobility. Consequently, DNA molecules can be pushed back to cis side and can form a highly concentrated DNA zone within the nanocapillary (Movie S3). The kymograph in b) shows the concentrated DNA zone moving towards the cis side by EOF and returning to the trans side once ethanol is added to the buffer to eliminate the electrical double layer on the capillary wall. Experimental conditions were identical as Fig. 4.
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